Classifications

• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61M—DEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
  • A61M5/00—Devices for bringing media into the body in a subcutaneous, intra-vascular or intramuscular way; Accessories therefor, e.g. filling or cleaning devices, arm-rests
  • A61M5/178—Syringes
  • A61M5/20—Automatic syringes, e.g. with automatically actuated piston rod, with automatic needle injection, filling automatically
  • A61M5/2033—Spring-loaded one-shot injectors with or without automatic needle insertion
• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61M—DEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
  • A61M5/00—Devices for bringing media into the body in a subcutaneous, intra-vascular or intramuscular way; Accessories therefor, e.g. filling or cleaning devices, arm-rests
  • A61M5/178—Syringes
  • A61M5/31—Details
  • A61M5/32—Needles; Details of needles pertaining to their connection with syringe or hub; Accessories for bringing the needle into, or holding the needle on, the body; Devices for protection of needles
  • A61M5/3202—Devices for protection of the needle before use, e.g. caps
  • A61M5/3204—Needle cap remover, i.e. devices to dislodge protection cover from needle or needle hub, e.g. deshielding devices
• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61M—DEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
  • A61M5/00—Devices for bringing media into the body in a subcutaneous, intra-vascular or intramuscular way; Accessories therefor, e.g. filling or cleaning devices, arm-rests
  • A61M5/178—Syringes
  • A61M5/31—Details
  • A61M5/32—Needles; Details of needles pertaining to their connection with syringe or hub; Accessories for bringing the needle into, or holding the needle on, the body; Devices for protection of needles
  • A61M5/3287—Accessories for bringing the needle into the body; Automatic needle insertion
• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61M—DEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
  • A61M5/00—Devices for bringing media into the body in a subcutaneous, intra-vascular or intramuscular way; Accessories therefor, e.g. filling or cleaning devices, arm-rests
  • A61M5/178—Syringes
  • A61M5/31—Details
  • A61M5/32—Needles; Details of needles pertaining to their connection with syringe or hub; Accessories for bringing the needle into, or holding the needle on, the body; Devices for protection of needles
  • A61M5/3287—Accessories for bringing the needle into the body; Automatic needle insertion
  • A61M2005/3289—Accessories for bringing the needle into the body; Automatic needle insertion with rotation of the needle, e.g. to ease penetration

Definitions

• the present invention relates to an autoinjector.
• Auto-injectors are well known in the state of the art. These devices are primarily intended to achieve an automatic injection of the contents of a syringe inside the body of a patient. Various systems exist to make automatic the penetration of the needle into the patient's body as well as the injection of the fluid contained in the syringe. Auto-injectors are relatively complex devices that must meet a number of constraint requirements to be reliable. The robustness of the device, its maneuverability, and its ease of use for the user are also important elements. Moreover, most of these autoinjectors are single-use, the cost of manufacturing and assembly is also a factor to consider.
• the devices must include reliable locking means.
• the device when a user wants to use the autoinjector and unlocks the device, for example by removing the cover, the device must not be triggered inadvertently but only when the user really wants, c that is to say at the moment when he applies it against the part of the body in which he wants to perform the injection.
• the autoinjector does not trigger itself. It is therefore important to have a reliable release lock.
• the time required to perform this injection can be quite large, which may especially exceed several seconds. It is therefore very important that the user does not remove the device from his body before the injection is complete. It is therefore desirable that the device comprises means for reliably indicating to the user that the injection is complete.
• the autoinjector must include a needle safety device that prevents the needle remains apparent after use of the device.
• This safety device must obviously also be reliable and not be released too easily. It must also be functional even if the user actuates the autoinjector badly, for example if he withdraws it too early from his body, before the end of the injection.
• Another important aspect with autoinjectors is to allow the product to diffuse from the injection site for a few seconds after said injection. If the user removes the autoinjector immediately after the end of the injection, part of the product can emerge from the body of the user which decreases the effectiveness of the treatment. It is therefore desirable to provide that the user maintains the autoinjector against his body for a few seconds after the end of the injection.
• This aspect is usually solved by the existing autoinjectors by the user manual that asks the user to count in his head a number of seconds before remove the device. This is not reliable and therefore unsatisfactory, because the system then depends on the user himself, which in some cases may be disrupted or weakened by the injection action he has just made.
• the present invention aims to provide an autoinjector which does not reproduce the aforementioned drawbacks, and which makes it possible to meet the various requirements and constraints important for safe and reliable use of the autoinjector.
• Another object of the present invention is to provide an autoinjector which is reliable in use, which makes it possible to guarantee the distribution of all the fluid product at the desired location, which enables the user to determine when to withdraw or when he can remove the autoinjector from his body after use, which is safe and which prevents any risk of injury, and which is simple and expensive to manufacture and assemble.
• the present invention therefore relates to an autoinjector comprising a lower body receiving a reservoir, said reservoir containing fluid and comprising a piston and a needle, such as a pre-filled syringe, said autoinjector comprising a central body attached to said lower body and an actuator sleeve provided with a contact end intended to come into contact with the user's body, said actuator sleeve being movable between a projected position and an actuating position, said actuator sleeve being in the projected position before and after actuating the autoinjector, injection means being provided for injecting said fluid product through said needle when said needle is in an injection position in which it is inserted into the body of the user, said autoinjector comprising a device tank displacement for on the one hand move the needle to said injection position and on the other hand retract said needle out of the body of the user after injection of the fluid product, said reservoir displacement device comprising a rotary mounted control ring in said central body, said control ring comprising a first inclined inner profile adapted
• said actuator sleeve in actuation position, cooperates with said reservoir displacement device to move said needle towards its injection position
• the autoinjector comprises an injection lock for blocking said injection means, said reservoir displacement device unlocking said injection lock and actuating said injection means when the needle is in the injection position.
• said injection means cooperate with said reservoir displacement device after injection of the fluid product to retract said needle.
• control ring unblocks the injection lock, actuating the injection means, said control slide cooperating with said control ring to again block the rotation of the injection said control ring.
• a trigger cooperates with said control slider after the end of the injection to move it axially to unlock again the rotation of said control ring, and thus move the reservoir to the retracted position of the needle.
• said actuator sleeve cooperates with said control slider such that when said actuator sleeve is returned to its projected position after or during actuation, said control slider is moved to the unlocking position of the rotation of the slider ring. command, to actuate the retraction of the needle.
• FIG. 1 is a schematic perspective exploded view of the components of an autoinjector, according to a first advantageous embodiment
• FIGS. 2a to 2f are diagrammatic cross-sectional views illustrating the different sequences of use of the autoinjector of FIG. 1,
• FIGS. 3a to 3c illustrate more precisely three different stages of an advantageous actuator sleeve, respectively before, during and after use
• FIG. 4 is a detailed view showing the actuator sleeve in the position of FIG. 3a
• FIGS. 5 and 6 are diagrammatic cross-sectional views along two different section planes showing the actuator sleeve in the position of FIG. 4,
• FIGS. 7 and 8 are partial cutaway schematic perspective views showing the actuator sleeve in the position of FIGS. 5 and 6,
• FIG. 9 is a view similar to that of FIG. 4, at the beginning of actuation of the autoinjector, during the stitching phase,
• FIGS. 10 to 11 are views similar to FIGS. 5 and 6, in the position of FIG. 9,
• FIG. 12 is a view similar to that of FIG. 8, in the position of FIGS. 10 and 11,
• FIG. 13 is a view similar to that of FIGS. 4 and 9 during actuation, in the injection phase,
• FIGS. 14 and 15 are views similar to those of FIGS. 10 and 11 representing the position of FIG. 13,
• FIG. 16 is a view similar to that of FIG. 12, showing the position of FIGS. 14 and 15,
• FIG. 17 is a view similar to that of FIG. 13, at the end of actuation, when the user removes the autoinjector from the injection site,
• FIG. 18 is a view similar to that of FIG. 17, when the actuator sleeve is locked
• FIG. 19 is a schematic perspective exploded view illustrating an advantageous injection lock
• FIG. 20 is a diagrammatic cross-sectional view of the injection lock of FIG. 19, in the locked position,
• FIG. 21 is a view similar to that of FIG. 20, in unlocking position
• FIG. 22 is a schematic view from above in horizontal section of the injection lock of FIG. 19, in the locked position
• FIG. 23 is a diagrammatic perspective view partially cut away of the injection lock of FIG. 19, in the locked position
• FIG. 24 is a diagrammatic cross-sectional view of the injection lock of FIG. 19, in the locked position
• FIG. 25 is a view similar to that of FIG. 23, in unlocking position,
• FIG. 26 is a view similar to that of FIG. 24 in unlocking position
• FIG. 27 is a schematic perspective exploded view of an advantageous retarder device
• FIG. 28 is a schematic cross-sectional view of the retarder device of FIG. 27 prior to its actuation
• FIG. 29 is a diagrammatic sectional view along section line X of FIG. 28,
• FIG. 30 is a diagrammatic sectional view along section line Y of FIG. 28,
• FIG. 31 is a view similar to that of FIG. 28, at the end of actuation of the delay device,
• FIG. 32 is an exploded schematic perspective view of an advantageous syringe displacement mechanism
• FIGS. 33 to 35 are schematic partially cut-away perspective views of the displacement mechanism of FIG. 32, before actuation, in three different orientations,
• FIGS. 36 and 37 are views similar to FIGS. 33 and 35, during actuation of the displacement mechanism
• FIGS. 38 to 41 are partial diagrammatic partial perspective views of the displacement mechanism of FIG. 32, when the syringe needle has reached its injection position in the body of the user,
• FIGS. 42 and 43 are schematic views of the movement mechanism of FIG. 32 at the beginning of retraction initiated by the retarder
• FIG. 44 is a schematic view of the movement mechanism of FIG. 32 at the beginning of retraction initiated by the actuator sleeve
• FIGS. 45 and 46 are views similar to FIGS. 43 and 44, at the end of the injection,
• FIG. 47 is a schematic perspective exploded view of the components of an autoinjector, according to a second advantageous embodiment
• FIGS. 48a to 48e are diagrammatic cross-sectional views illustrating the different sequences of use of the autoinjector of FIG. 47,
• FIGS. 49a and 49b are diagrammatic perspective views illustrating the lower body and the actuator sleeve of the autoinjector of FIG. 47,
• FIGS. 50a, 50b and 50c schematically illustrate the cooperation between the actuator sleeve and the lower body of the autoinjector of FIG. 47, respectively in the position before actuation, after actuation but before injection and after injection,
• FIG. 51 is a view similar to that of FIG. 50a, illustrating an alternative embodiment
• FIG. 52 is an enlarged detail view in cut-away perspective, showing a variant of an actuator sleeve with breakable bridges
• FIGS. 53a and 53b illustrate schematic views of the autoinjector before injection
• FIGS. 54a and 54b are views similar to FIGS. 53a and 53b, after injection,
• FIG. 55 is a schematic perspective view of an audible and / or tactile indication device according to an advantageous variant
• FIG. 56 is a view similar to FIG. 55, partially in section,
• FIGS. 57a, 57b and 57c show the autoinjector before injection
• FIGS. 58a, 58b and 58c show the autoinjector after injection but before actuation of the audible and / or tactile indication device
• FIGS. 59a, 59b and 59c show the autoinjector after injection and after actuation of the audible and / or tactile indication device
• FIG. 60 is a schematic exploded perspective view illustrating an alternative embodiment of the audible and / or tactile indication device
• FIGS. 61 and 62 are schematic views of the control sleeve of the audible and / or tactile indication device of FIG. 61,
• Figs. 63a and 63b are schematic views of the key of the audible and / or tactile indication device of Fig. 61,
• FIGS. 64a, 64b and 64c are diagrammatic views of the autoinjector of FIG. 60, respectively before unlocking the injection lock, after unlocking the injection lock and at the end of the injection, illustrating the device of FIG. audible and / or tactile indication of figure 61,
• FIG. 65 shows another variant embodiment of the audible and / or tactile indication device
• Figs. 66a and 66b are schematic views of the support pad of the audible and / or tactile indication device of Fig. 65,
• FIGS. 67a and 67b are schematic views of the key of the audible and / or tactile indication device of FIG. 65,
• FIGS. 68a, 68b and 68c are views similar to FIGS. 64a, 64b and 64c, illustrating the audible and / or tactile indication device of FIG. 65,
• Figs. 69, 70 and 71 are detailed views of Figs. 68b and
• FIG. 72 schematically shows an alternative embodiment of the actuator sleeve
• FIG. 73 shows another view of the variant embodiment of FIG. 72.
• FIGS. 74a, 74b and 74c are views similar to FIGS. 50a, 50b and 50c, illustrating the variant embodiment of the actuator sleeve of FIGS. 71 and 72.
• the autoinjector will be described hereinafter with reference to various variants of two advantageous embodiments thereof.
• a first embodiment is shown in Figures 1 to 46 and a second embodiment is shown in Figures 47 to 74c.
• these autoinjectors which are complex devices, include several modules to perform several functions. These various modules can be used separately and independently of each other, without necessarily being combined with other modules, and could in particular be used in autoinjectors of different shape from that shown in the drawings.
• the autoinjector comprises a central body 1, a control ring 2, a stitching spring 3, a control sleeve 4, a piston rod 5, a support pad 6, three locking elements 7, here in the form of balls, an injection spring 8, a control slider 9, a lower body 10, an actuator sleeve 1 1, a spring 12 of the actuator sleeve, a housing of reservoir 13, a hood 14, an upper body 15, a plurality of planetaries 16, a plurality of satellites 17, a delaying spring 18, a trigger 19, a locking pin 20, a wire 21, an outer shell 22 and a ring 23. All these elements are part of the embodiment described, but all are not essential to the operation of the autoinjector, as will be more specifically described below.
• the cover 14 allows in particular to lock the autoinjector during transport and storage. As long as this hood is assembled on the lower body 10, it prevents any actuation of the actuator sleeve 1 1, and therefore any triggering of the autoinjector.
• a tank A can be inserted into said autoinjector.
• This reservoir contains fluid, and comprises a piston and a needle.
• the piston is adapted to move in said reservoir to inject the fluid product to through said needle.
• a syringe A which can be of any type. More generally, it is understood that the term "syringe" in this specification encompasses any type of tank associated with a needle.
• the syringe A is a pre-filled syringe. It advantageously comprises a needle cap B which protects and isolates the needle before use of the autoinjector.
• this needle cap B is automatically withdrawn when the cover 14 is withdrawn from the lower body 10.
• FIGS 2a to 2f illustrate the sequences of the use of the autoinjector of Figure 1.
• the user wants to use the autoinjector, he takes the device, for example at the outer shell 22 and he presses the actuator sleeve 1 1, which in a first projected position protrudes out of the lower body 10, against the part of the body where he wants to perform the injection.
• FIG. 2b it can be seen that the pressure exerted by the user on the actuator sleeve 11 causes the latter to slide towards the inside of the lower body 10, with the effect of compressing the spring of the actuator sleeve 12.
• the actuator sleeve 1 1 When the actuator sleeve 1 1 reaches its actuating position, which is its end position inside the lower body 10, it triggers the stitching lock and thus the displacement of the control sleeve 4 in the body under the effect of the stitching spring 3, with the result that the syringe A is displaced in the lower body 10 and thus the syringe needle is inserted into the body of the user, as can be seen in FIG. Figure 2c.
• the autoinjector provides a retraction of the syringe A.
• the needle is retracted out of the body of the user to the inside the autoinjector, as shown in Figure 2e.
• the actuator sleeve 1 1 is again moved out of the lower body 10 to a second projected position, under the effect of the spring 12 of the actuator sleeve, with a locking of said actuator sleeve January 1, which guarantees a safety absolute for the user and avoids any risk of injury with the needle after use of the device.
• the first and second projected positions of the actuator sleeve which, in the example shown, are different positions, could possibly be identical.
• Said actuator sleeve 1 1 comprises a flexible tab 1 10 which has a double flexibility. It is on the one hand radially flexible, that is to say that it deforms towards the inside of the actuator sleeve 1 January. It is then also laterally flexible that is to say that it deforms in the peripheral direction of the actuator sleeve 1 January.
• An actuator sleeve January 1 provided with such a flexible tab is simple to mold, which is favorable from the point of view of manufacturing costs.
• the flexible tab 1 10 advantageously comprises a portion of rod 1 1 1 which is flexible and which ends with a head portion 1 12.
• Said flexible tab 1 10 is adapted to deform on the one hand radially and on the other hand laterally relative to said central body 1 when said actuator sleeve 1 1 is moved from its first projected position to its actuated position and then from its actuated position back to its second projected position.
• said flexible tab 1 10 is deformed radially when said actuator sleeve 1 1 moves from its first projected position, before actuation, towards its actuating position, and said flexible tab is deformed laterally when said actuator sleeve 1 1 moves from its actuating position to its second projected position, at the end of use. It is this variant which is represented in the figures.
• FIGS. 3a, 3b and 3c are three partial schematic perspective views which show the end positions of the actuator sleeve 1 1, namely in FIG. 3a the first projected position at rest before actuation, in FIG. 3b the position of FIG. actuation in which the actuator sleeve 1 1 has been inserted as far as possible inside the lower body 10, and in FIG. 3c the second projected position with the actuator sleeve 1 1 locked relative to the lower body 10, at the end of use .
• the central body 1 has cutouts forming grooves and shoulders which are detailed below.
• the central body 1 is fixed to the lower body 10 and the actuator sleeve 1 1 is slidably disposed inside said lower body 10.
• the central body 1 comprises a first groove 101, substantially axial, and an opening 103, separated from said first groove 101 but disposed in the axial extension of said first groove 101.
• Said central body 1 also comprising a radial cam 102 disposed between said first groove 101 and said opening 103.
• said radial cam 102 may be formed by an inclined radial thickening of the wall of the central body 1 said thickening being formed at the axial end of the first groove 101.
• Said radial cam 102 cooperating with said head 1 12 of said flexible tab 1 10 to radially deform said flexible tab 1 10 and thus allow said head 1 12 to pass from said first groove 10 to said opening 103 during the displacement of the actuator sleeve 1 1 to its actuating position.
• Said central body 1 comprises a final receiving zone 105 offset axially and laterally with respect to said opening 103. As can be seen in the figures, this final receiving zone 105 is disposed axially approximately at the level of said first groove 101.
• the opening 103 is connected to said final receiving zone 105 by a laterally inclined groove 104.
• An axial shoulder 106 is provided between said final receiving zone 105 and said inclined groove 104.
• said actuator sleeve 1 1 When said actuator sleeve 1 1 reaches its second projected position, after use, said head 1 12 snap under said axial shoulder 106, thereby locking said actuator sleeve 1 1 relative to said central body 1 and relative to the lower body 10. From this locked position, said actuator sleeve can no longer be moved towards its actuating position, from the stop formed between the head 1 12 of the flexible tab 1 10 and the axial shoulder 106.
• Figures 4 to 8 show the starting position, that is to say when the user will start using the autoinjector. It can be seen in these figures that the head 1 12 is disposed in said axial groove 101 of the central body 1. When the actuator sleeve 1 1 slides inwardly of the lower body 10, said head 1 12 of the flexible tab 1 10 will slide inside said groove 101 of the central body. When the head 1 12 reaches the axial end of the first groove 101, said radial cam 102 will cooperate with said head 1 12. This radial cam 102 will deform the flexible lug 1 10, and in particular its rod portion 1 1 1 radially inward towards its longitudinal central axis.
• Figures 9 to 12 illustrate the position in which the flexible tab 1 10 is radially deformed. As can be seen in particular in FIG. 11, after this radial deformation, the head 1 12 of the flexible lug 1 10 will continue to move axially for a further distance until it reaches said opening 103. The actuator sleeve 1 1 then reaches its actuating position, as shown in Figure 13.
• the actuator sleeve 1 1 When the actuator sleeve 1 1 reaches its actuating position, that is to say in the position of Figures 13 to 16, the spring 12 of the actuator sleeve has been compressed and the stitching lock is triggered by said actuator sleeve 1 1, as will be more fully described later, which causes the movement of the syringe A inside the lower body 10 and thus the stitching of the needle in the body of the user.
• the actuator sleeve 1 1 does not move relative to the lower body 10, since the user maintains its pressure on the part of the body in which he performs the injection.
• the spring 12 of the actuator sleeve 1 1 will urge said actuator sleeve 1 1 back from its actuating position to its second projected position, as is shown in Figure 3c.
• the head 1 12 of the flexible lug 1 10 will cooperate with the inclined groove 104 as visible in Figures 17 and 18. This will cause an elastic deformation of the flexible tab 1 10, including its part of rod 1 1 1, as the actuator sleeve 1 1 will slide axially, the head 1 12 sliding in said inclined groove 104 laterally deforming said flexible tab 1 10 as clearly visible in Figure 17.
• This inclined groove 104 ends in a final receiving zone 105 provided with an axial shoulder 106.
• the head 1 12 of the flexible tab 1 10 will enter this final receiving zone 105 and the upper edge 1 14 of the head 1 12 will come to cooperate with the axial shoulder 106, which will block the actuator sleeve 1 1 relative to the lower body 10.
• the actuator sleeve 1 1 can then no longer slide axially towards the inside of the body lower 10, and the safety device is then in locked end position.
• the needle is completely protected after use and the user can no longer use the autoinjector or injure himself with the needle.
• the shapes of the grooves, their dimensions and their inclinations can be modified according to the needs and characteristics desired for the needle safety device.
• the actuator sleeve described above is particularly effective and reliable, while being robust and easy and therefore inexpensive to mold.
• FIGS. 32 to 46 more particularly describe the device for moving the syringe in the lower body 10.
• This displacement device ensures, on the one hand, the stitching, that is to say the insertion of the needle into the body of the user, and secondly the retraction of the needle after injection.
• the syringe A is moved axially in said lower body 10 to carry out the insertion of the needle into the body of the user.
• the syringe A is again moved in the other direction inside the lower body 10, to be retracted and thus automatically remove the needle from the body of the user. In this way when the user removes the autoinjector from his body, the needle is no longer projecting but instead retracted inside said autoinjector.
• a control ring 2 which cooperates with the control sleeve 4, with the control slider 9 and with the actuator sleeve 1 1. Furthermore, the trigger 19 intervenes to achieve the retraction of the syringe inside the body as will be explained below.
• FIGs 33 to 35 illustrate the starting position before the syringe is moved for tapping. It is found that the control ring 2 is urged in rotation by the stitching spring 3, which here is a spring acting in torsion. Such a torsion spring makes it possible to perform a non-painful stitching.
• the control ring 2 comprises three inclined profiles 24, 25, 26 similar to ramps, the functions of which will be explained hereinafter.
• the control ring 2 comprises a first inclined inner profile 24, such as a ramp, which will cooperate with a projection 44 of the control sleeve 4.
• This control sleeve 4 cooperates with the syringe housing 13 which receives the syringe, and thus a displacement of the control sleeve moves the syringe A in the lower body 10 to perform the stitching of the needle.
• FIG. 39 illustrates the position in which the needle is fully inserted, with the first inclined profile 24 which cooperates with the projection 44 of the control sleeve 4.
• the projection 91 of the control slider is also in contact with an external inclined profile 25 of the ring 2, such as an external ramp, which will cause additional axial movement of said control slider 9 relative to the actuator sleeve 1 January. This will move the control slider 9 in the same direction as the actuator sleeve 11 during stitching. As a result, the projection 92 of the control slider 9 comes close to an upper projection 1 19 of the actuator sleeve 1 1, and the projection 95 of the control slider 9 comes close to a projection 191 of the trigger 19, as visible on Figure 44.
• the first internal inclined ramp 24 which cooperates with the projection 44 of the control sleeve 4 advantageously comprises a plate 241, that is to say a non-inclined portion, visible in FIG. 41.
• This dish 241 has a very important function since it ensures that the beginning of the injection will occur only after the complete end of the needle insertion into the body of the user. While for many autoinjectors it is necessary to start the injection a little before the needle reaches its final insertion point, for reasons of manufacturing tolerance, the plate 241 on the ramp 24 avoids this. phenomenon.
• the ring 2 has already completely moved the control sleeve 4 axially and thus has achieved the total insertion of the needle of the syringe into the body of the user, it is necessary that the ring 2 turns again. on the arc formed by said flat, for example about 30 °, to trigger the injection lock.
• the locking ring 23 of the injection lock is moved out of its locking position only after the additional rotation of the ring 2 on the circular arc formed by said plate 241.
• control ring 2 comprises three second internal inclined profiles 26 arranged at 120 ° from each other, and the locking ring 23 comprises three projections 235 also arranged at 120 ° from each other, a respective projection 235 cooperating with a second respective internal inclined profile 26.
• the spring 12 of the actuator sleeve 1 1 will urge said actuator sleeve 1 1 back out of the lower body 10.
• This displacement of the actuator sleeve 1 1 will pull the control slider 9 axially downwards in FIG. 44 by the cooperation between the upper shoulder 1 19 and the projection 92 of the slider.
• the control ring 2 will again be released in rotation by the control slider 9, and the spring 3 will urge this control ring further in rotation which will cause the retraction of the syringe and the needle to the inside the body.
• the actuator sleeve 1 at the end of movement, will be locked as described above. Thus, even if the user removes the autoinjector before the end of dispensing the product, the needle safety device is operative.
• Figures 45 and 46 illustrate the retraction of the needle with the rotation of the ring 2 which will bring the projection 44 of the control sleeve facing an internal groove of the ring 2, which will cause, under the effect of the spring, the axial displacement back of the control sleeve 4 inside the control ring 2 and thus the retraction of the syringe and the needle.
• FIGS 19 to 26 schematically illustrate an advantageous injection lock.
• the autoinjector comprises injection means, comprising in particular the piston rod 5, the injection spring 8 and the locking ring 23, these injection means being locked in a position loaded by said injection lock.
• the unlocking of said injection lock then causes the actuation of said injection means and thus the injection of the fluid product through the needle.
• said injection lock comprises a control sleeve 4 disposed in said central body 1, said control sleeve 4 containing said piston rod 5 and said injection spring 8, said piston rod 5 comprising a radial recess 50 receiving at least one locking element 7 movable between a locking position and an unlocking position.
• Said at least one blocking element 7 is preferably of substantially spherical shape.
• Said balls 7 are biased radially outwardly by said piston rod 5 and are retained in the locking position by a locking member, which in this embodiment is formed by a locking ring 23.
• This locking ring 23 is axially displaceable relative to said piston rod 5 between a locking position, in which it holds the locking elements 1007 in the locking position, and an unlocking position, wherein said locking elements 1007 are released to thereby unlock said lock injection, allowing said injection spring to move said piston rod 5 to its injection position.
• Figure 20 shows the injection lock in the locking position.
• the injection spring 8 cooperates on the one hand with the piston rod 5 and on the other hand with a support pad 6.
• This support pad 6 is formed by a ring disposed around said piston rod 5.
• the piston rod 5 comprises a peripheral recess 50, advantageously provided with an inclined surface 51, formed by a narrowing of the diameter of said piston rod 5.
• This piston rod 5 is disposed inside the control body 4 and is capable of move axially to the left in FIG. 20 to push the plunger of syringe A inside the syringe and deliver the fluid contained in said syringe through the needle.
• the balls 7 are disposed in said recess 50 formed in the piston rod 5 and thus cooperate with the inclined wall 51 of the piston rod 5 and with the upper surface on the one hand. 61 of said support pad 6.
• the inclined surface 51 of the piston rod is in contact with the balls 7 so that under the effect of the compressed spring 8, said inclined surface 51 exerts a reaction force F1 on the balls 7, this force F1 not being exactly axial but directed slightly outward, thereby biasing the balls 7 radially outwardly of the locking position of FIG. 20.
• the locking ring 23 is provided radially outside the balls 7 to radially block said balls in the locking position.
• the balls may be arranged in housings of the control sleeve 4, the locking ring 23 comprising projections 231, one for each ball 7, which are positioned in contact with the balls. balls 7 to prevent them from being displaced radially outwards.
• the pellet 6 transmits the force F3 of the spring 8 to the balls 7, and the locking ring 23 exerts a reaction force F2 on the balls 7 to prevent a radial displacement thereof.
• the balls 7 which support all the forces exerted on the lock in the locking position, with a balance in three points under the effect of the forces F1, F2 and F3.
• Such a lock is particularly stable and robust, and in particular to withstand drops tests. These tests simulate the fact of dropping the autoinjector on the ground after removing the cover 14, the objective being to avoid a triggering of the injection lock during this fall. In particular, no force is exerted on the structural parts of the autoinjector, such as the central body 1 or the lower body 10. This lock thus avoids the risk of inadvertent disassembly of the device during transport or handling.
• balls 7 could be replaced by non-spherical elements but of rounded shape more complex, for example in the form of cylinder or bean, to further improve the stability of the lock.
• these non-spherical movable elements could be made of metal, for example by cutting steel wire.
• the locking ring 23 is moved according to the arrow E1 in FIG. This has the effect of releasing the balls 7 from their locking position, these being then displaced radially outwardly along the arrow E2.
• the locking ring 23 could also be rotated to a position where it releases the balls.
• the support pad 6 then comes into abutment against an inner edge of the control sleeve 4 as represented by the arrow E3 in FIG. In this position, the piston rod 5 is no longer retained by the balls 7 and is thus moved axially, that is to say to the left in Figure 21, to perform the injection of the product.
• the balls 7 can no longer return to the blocking position, prevented by the patch 6, as visible in FIG. 21.
• FIGs 23 to 26 illustrate with slightly different views the two locking and unlocking positions of the injection lock as described above with reference to Figures 20 and 21.
• the injection lock shown in FIGS. 19 to 26 makes it possible to unlock a large force exerted by a compressed spring, in this case the injection spring 8, by exerting a relatively weak force that is easily controllable on the locking ring 23.
• the force required to move said locking ring 23 in the unlocking position may represent only 10%, or even only 5%, of the force exerted by the injection spring 8. This represents a very important yield which guarantees easy and reliable operation of the device.
• a trigger 19 is actuated to retract the syringe and thus the needle.
• a locking finger 20 extends through the trigger 19 and into the central channel 151 of the upper body 15.
• This rotation is blocked by the locking finger 20, advantageously of oblong shape, which is adapted to rotate together with said trigger 19, but which is blocked in rotation by said central channel 151 of the upper body 15.
• the piston rod 5 moves axially, that is to say to the left in FIG. 28. As it moves, it will pull on the wire 21 which will therefore extend out of the channel 151.
• the rotation of the trigger 19 is blocked.
• the trigger 19 comprises an inclined external ramp 190 which may comprise on one side a projection 191.
• this projection 191 will cooperate with the control slider 9, which will move it axially and thus trigger the retraction of the needle, as has been previously described.
• FIG. 27 to 31 illustrate an advantageous delay device.
• This delaying device which is optional in an autoinjector, is mainly intended to shift in time the retraction of the syringe A and therefore the needle out of the body of the user after the end of the injection of the fluid product. inside said body. This allows in particular a diffusion for a few seconds of the product after its injection.
• Such a retarder also provides a benefit for the user, who no longer has to count, for example up to 10, after its injection, the time taken for this count can be very variable from one user to another. With a self-timer, the sequence of use of an autoinjector is facilitated.
• the mechanical retarder shown in FIGS. 27 to 31 makes it possible to shift this retraction a few seconds, this delay being predeterminable.
• Figure 27 illustrates an exploded schematic view of this delay device.
• This comprises the upper body 15, several planetaries 16 with several satellites 17, the delay spring 18, the trigger 19, the locking pin 20, the wire 21 and the piston rod 5. It is this rod of piston 5 which will perform the actuation of the delay device when it reaches the end of the injection stroke with all the product that has been injected.
• Figure 28 shows the delay device before it is actuated. It can be seen that the actuating rod 5 is connected to the locking finger 20 via the wire 21. In this position, the wire 21 and the locking finger 20 extend inside a central channel 151 of the upper body 15 and in the trigger 19.
• the upper body 15 has a gear 155 on its lateral internal surface, as shown clearly in FIG. 30. This internal gear 155 of the upper body 15 cooperates with a plurality of satellites 17 which are assembled on planetary gears 16. In the example shown in FIG. 28, there are several planetary axles stacked axially. on the other.
• the planet gears 16 comprise a disk-shaped plate on which satellite support rods 161 are formed on one side, each of which receives a satellite 17 in rotation.
• each sun gear 16 associated with its satellites 17 forms a stage of the delaying device.
• the sun gear 16 has a gear 162 adapted to cooperate with the satellites 17 of the adjacent stage.
• the delaying device uses the principle of epicyclic gear trains. Each stage of this device makes it possible to increase and / or slow down the rotations of the previous stage.
• the trigger 19 cooperates with a first sun gear 16, whose rods 161 extend inside said trigger 19.
• the gear 162 of the first sun gear 16 then cooperates with the satellites of a second planetary adjacent, which cooperate with the lateral gear 155 of the upper body 15, thereby multiplying the rotation of the first sun gear and therefore the trigger, and thus curbing this rotation.
• Each additional stage of the epicyclic gear train forming the retarder will further reduce these rotations, and thus further reduce the rotation of the trigger 19.
• Friction braking can also be provided, for example between the satellites 17 and the internal gear 155 of the upper body 15.
• the delay device thus makes it possible to shift by a predetermined time the moment when said trigger will actuate the retraction of the needle, from the moment when the injection phase is completed.
• the principle of the deployable wire connected on the one hand to the piston rod 5 and on the other hand to the locking pin 20 can be used without the epicyclic gear system as shown in FIGS. 27 to 31 , as will be described in particular below with reference to the second embodiment.
• This thread very compact, ensures that the retraction of the needle does not begin until the injection phase is completely completed, allowing in particular to compensate for any manufacturing tolerances.
• the use of a wire reduces the size of the device. Therefore, it can be used advantageously for different functions in an autoinjector, since it is necessary to draw a piece relative to another.
• the outer shell 22 comprises several indicators that make it possible to inform the user of the progress of the quilting, injection and retraction sequences.
• a delay device it is also possible to provide a display of said delay.
• the outer shell 22 can comprise several viewing windows, in this case three windows 221, 222, 223, which make it possible to display moving elements during different phases of actuation, these elements comprising indicators, typically colors.
• control slider 9 which at rest is in a first position relative to the central body 1, moves axially towards a second position during the displacement of the actuator sleeve 1 January. It then remains in this second position during the whole injection phase, and returns towards its first position during the retraction of the needle. Only when the actuator sleeve returns to its second projected position, the control slider reaches this first position.
• This control slider 9 may comprise one or more color indicators, for example a red horn zone visible in FIG. 1. This slider can therefore be used to indicate on the one hand the projected position of the actuator sleeve 1 1 (first position) and secondly the stitching and injection phase (second position).
• the trigger 19, which triggers the retraction of the needle at the end of injection may also include an indicator, for example a red zone, which is displayed when said trigger has achieved its predefined rotation and thus actuated the retraction of the needle.
• the first viewing window 221 may be the end of injection window, that is to say that when a predefined color, for example red, appears in the window 221, the injection is completed and the syringe has been retracted.
• the user therefore knows that when this first viewing window is red, he can remove the autoinjector safely from his body.
• This indication may for example be provided by the trigger 19.
• the second viewing window 222 may be that of the stitching and injection phases, which goes red during the beginning of the stitching phase at the end of the injection phase. This prevents the user from removing the autoinjector body during these phases, which can last several seconds. This indication can be provided by the actuator slide 9.
• the third viewing window 223 may be that of the actuator sleeve 1 1, with the red displayed when the actuator sleeve 1 1 is in a projected position out of the lower body.
• This third viewing window 223 is red before operation, then again after use, when the actuator sleeve 1 1 is locked in the safety position.
• This indication can be provided by the control slider 9.
• the red zone of the actuator slider 9 passes from the third viewing window 223, before actuation (FIG. 2a) to the second viewing window 222 (FIG. 2c ) when the actuator sleeve is in the actuating position where it triggers the stitching phase. During this transition, said red zone is not visible, being located between said windows 223 and 222 (FIG. 2b).
• the control slider remains in its second position ( Figure 2c & Figure 2d).
• the control slider 9 is again moved axially towards its first position by the trigger 19, to actuate the retraction of the needle, the red zone passes back from the second window 222 to the third window 223, being again invisible (FIG. 2e), finally reappearing in the third window 223 when the actuator sleeve is locked in the second projected position (FIG. 2f).
• the combination of the red in the first and third viewing windows 221 and 223 guarantees the end of the process of using the autoinjector, with the needle retracted and the actuator sleeve 1 1 locked, which guarantees safety optimal.
• said outer shell 22 may comprise any number of viewing windows, of any shape and size, and which could be positioned differently from the represented variant. in the figures.
• a single window can display several different functions.
• the state of the delaying device for example with a countdown.
• This one could be realized for example with numerical values written on the external lateral edge of the shutter which progressively passes in a suitable viewing window and which displays in seconds the countdown of the self-timer.
• Other variants are of course also possible.
• This outer shell 22 may also include one or more buttons stitching and / or retraction of the needle, if the autoinjector provides such buttons to perform the stitching and / or retraction of the needle.
• the outer shell 22 could also include a temperature indicator of the product to be injected. Indeed, many products to be injected are stored at 8 ° and it is often recommended to take them out 30-60 min in advance. If the product is too cold at the time of injection, this can cause pain in the patient.
• the shell 22 could include a display of the temperature of the tank containing the product to be injected. Alternatively, it could also provide a label that changes color with temperature. This temperature indicator could be provided on the shell, or on the tank, including the syringe, and be visible through a window of the hull.
• Figures 47 to 74c illustrate several variants of a second embodiment of the invention.
• This second embodiment relates to a simplified autoinjector, consisting of fewer parts, and therefore simpler and less expensive to manufacture and assemble.
• the autoinjector comprises a lower body 1010, an actuator sleeve 101 1, a spring 1012 of the actuator sleeve, a cover 1014, a control sleeve 1004, a piston rod 1005, a support pad 1006, three locking elements 1007, here in the form of balls, an injection spring 1008, a click member 1500, a wire 1021, and an outer shell 1022.
• the cover 1014 makes it possible in particular to lock the autoinjector during transport and storage. As long as this cover is assembled on the lower body 1010, it prevents any actuation of the actuator sleeve 101 1, and therefore any triggering of the autoinjector.
• the syringe A is a pre-filled syringe. It advantageously comprises a needle cap B which protects and isolates the needle before use of the autoinjector.
• this needle cap B is automatically withdrawn when the hood 1014 is withdrawn from the lower body 1010.
• this second embodiment has several elements similar to the first embodiment, these similar elements being designated by numerical references similar to those of the first embodiment, increased by 1000.
• the actuator sleeve referenced 1 1 in the first embodiment is now referenced 101 1. Therefore, in the description of this second embodiment, it is mainly the differences with respect to the first embodiment that will be described, it being understood that the other elements and functions remain similar if not identical between the two embodiments.
• the main difference of this second embodiment is that the reservoir, in this case the syringe A, is fixed with respect to the lower body 1010, with respect to the control sleeve 1004 and with respect to the outer shell 1022. to perform the stitching of the needle, only the actuator sleeve slides relative to the rest of the autoinjector. There is therefore not in this second embodiment of syringe displacement device.
• FIGS 48a to 48e illustrate the sequences of the use of the autoinjector of Figure 47.
• the user wants to use the autoinjector, he takes the device, for example at the outer shell 1022 and presses the actuator sleeve 101 1, which in a first projected position protrudes out of the lower body 1010, against the part of the body where he wants to perform the injection.
• the pressure exerted by the user on the actuator sleeve 101 1 causes the latter to slide towards the interior of the lower body 1010, which discovers the needle and therefore its stitching due to the pressure exerted by the user on the autoinjector.
• the actuator sleeve 101 1 is again moved out of the lower body 1010 to a second projected position, under the effect of the sleeve spring actuator, with a locking of said actuator sleeve 101 1, which guarantees absolute safety for the user and avoids any risk of injury with the needle after use of the device.
• the first and second projected positions of the actuator sleeve which, in the example shown, are different positions, could possibly be identical.
• said actuator sleeve 101 1 also comprises a flexible tab 11 which is flexible only laterally, that is to say that it does not deforms only in the peripheral direction of the actuator sleeve
• the flexible tab 1 1 10 advantageously comprises a portion of rod 1 1 1 1 which is flexible and which ends with a head portion 1 1 12.
• said flexible tab 1 1 10 is adapted to deform laterally with respect to said lower body 1010 on the one hand when said actuator sleeve 101 1 is moved from its first projected position to its actuating position and secondly when said actuator sleeve 101 1 is moved from its actuating position back to its second projected position.
• the head 1 1 12 of the flexible tab must overcome a resistance to deform laterally at the beginning of the actuation, to create a kind of precompression which ensures that when the actuator sleeve will slide inward of the lower body 1010, the needle goes constantly to the injection site to its desired injection position.
• this resistance is formed by a shoulder 1019 of the lower body 1010.
• said flexible lug 1 1 10 is not deformed when said actuator sleeve 101 1 moves from its first projected position, before actuation, to its actuating position, and said flexible tab is laterally deformed only when said actuator sleeve 101 1 moves from its actuating position to its second projected position, at the end of use.
• the actuator sleeve 101 1 before actuation, is connected to said lower body 1010 by at least one breakable bridge 1500.
• This embodiment allows in particular easy molding, and therefore reduced manufacturing costs, adaptation and management of the breaking force of the breakable bridges facilitated by the dimensioning of these bridges, and a control function of use.
• Figure 52 illustrates two breakable bridges 1500, adapted to break and thus to allow a sliding of the actuator sleeve 101 1 relative to the lower body 1010 when the user presses the autoinjector at the injection site with a predetermined pressure.
• the operation of the flexible tab 1 1 10 may be identical to that described in the context of the first embodiment, with an inclined groove, a final receiving zone and an axial shoulder cooperating with the head of the flexible tab to block it in the second projected position.
• the lower body 1010 may include a shoulder 1019 which extends axially inwardly by a ramp 1018, for example formed by a rib, which is at least partially inclined.
• a ramp 1018 for example formed by a rib, which is at least partially inclined.
• this same projection 1019 can cooperate with the head 1 1 12 of the flexible lug 1 1 10 both at the beginning of actuation to create the precompression and at the end of actuation to lock the actuator sleeve in second position projected.
• the flexible lug 1 1 10 can be attached to said actuator sleeve 101 1 only at its rod portion 1 1 1 1, with in this case the head 1 1 12 forming a free end of said flexible tab.
• the flexible tab could also be attached to said actuator sleeve on both sides, thus with the head 1 1 12 disposed between the two attachment points. This implementation reinforces in particular the robustness of the flexible tab. This variant could also be adapted to the flexible tab of the first embodiment.
• the flexible tab 1 1 10 of the actuator sleeve 101 1 advantageously cooperates with an opening 103, an inclined groove 104, a final receiving zone 105 and an axial shoulder 106 of the body 1010 which are similar to these same elements described above with reference to FIGS. 4 to 18.
• Figures 72 to 74c illustrate another alternative embodiment of the actuator sleeve.
• the numerical references will be similar to those above, but increased by 1000.
• the actuator sleeve will be referenced 201 1.
• the functions of the actuator sleeve 201 1 and the body 2010 are reversed, the body 2010 comprising the flexible lug 21 10, and the actuator sleeve 201 1 having the profile which will cooperate with said flexible lug 21 10.
• the operation however remains similar to that described above, with the flexible tab 21 10 which will gradually slide in said profile, and in particular in an inclined groove 2104 which connects an opening 2103 to a final receiving area 2105.
• the flexible tab 21 will snap onto the shoulder 2106, as shown in Figure 74c.
• the flexible tab must advantageously overcome a resistance to deform at the beginning of the actuation, to create a kind of precompression which ensures that when the actuator sleeve 201 1 will slide inward of the lower body 2010, the The needle will constantly penetrate the injection site to its desired injection position. In the example of FIGS. 72 to 74C, this resistance is formed by a shoulder 2019 of the actuator sleeve 201 1.
• the flexible tab 21 can be integrally formed on the body 2010, or alternatively be formed on a separate part assembled on said body 2010, for example for reasons of simplification and / or molding.
• FIGS. 53a, b, 54a, b, 57a, b, c and 58a, b, c illustrate the adaptation to the second embodiment of the injection lock described in the first embodiment.
• the autoinjector comprises injection means, including in particular the piston rod 1005 and the injection spring 1008, these injection means being locked in a position loaded by said injection lock.
• the unlocking of said injection lock then causes the actuation of said injection means and thus the injection of the fluid product through the needle.
• said injection lock comprises a control sleeve 1004 disposed in said outer shell 1022, said control sleeve 1004 containing said piston rod 1005, said injection spring 1008 and a support pad 1006.
• the injection spring 1008 cooperates on the one hand with the piston rod
• Said piston rod 1005 comprising at least one radial recess 1050 receiving at least one locking element 1007 movable between a locking position and an unlocking position.
• there are three locking elements 1007 preferably of substantially spherical shape, in particular in the form of balls, but a different number of locking elements and different rounded shapes of these locking elements are possible.
• Said locking elements 1007 are biased radially outwardly by said piston rod 1005 and are retained in the locking position by a locking member, which in this second embodiment is formed by said control sleeve 1004.
• This sleeve control 1004 is axially movable relative to said piston rod 1005 between a locking position, in which it holds the locking elements 1007 in the locking position, and an unlocking position, wherein said locking elements 1007 are released thereby unlocking said injection lock, allowing said injection spring to move said piston rod 1005 to its injection position.
• the control sleeve 1004 comprises one or more windows 1400 which allow the blocking elements 1007 to pass when the control sleeve has been moved towards its unlocking position, represented in particular in FIGS. 58.
• the displacement of the control sleeve 1004 from its locking position to its unlocking position is achieved by a projection 141 1 of the actuator sleeve 101 1, which will cooperate with a shoulder 1410 of the control sleeve 1004, so that the control sleeve 1004 is in the unlocked position when the actuator sleeve 101 1 is in the actuating position.
• Said piston rod 1005 is then no longer blocked by said locking members 1007, it is moved out of the control sleeve by said pre-compressed injection spring 1008 to move the piston into the reservoir and thereby inject the product through the needle.
• This type of lock allows a low effort release thus ensuring a sound and tactile comfort to the user during the injection.
• the autoinjector comprises an audible and / or tactile indication device 1500 for indicating by an audible sound or by a tactile indication to the user that the injection phase is complete.
• This device will be described below in connection with three variants of the second embodiment, but it could also be adapted to an autoinjector made according to the first embodiment.
• this sound and / or tactile indication device 1500 comprises a central part 1501 provided with at least one lateral piece 1502 connected to said central piece 1501 by a foldable and / or divisible connection 1503.
• a foldable and / or divisible connection 1503. In the example shown in Figures 55 to 59c, there are two side pieces 1502 each connected to the central part by a breakable connection.
• the central part 1501 is connected to said piston rod 1005 by said wire 1021, which is fixed on the one hand to said central part 1501 and on the other hand to said piston rod 1005.
• the wire 1021 is wound around the piston rod and the central piece 1501 is disposed outside the control sleeve 1004.
• the control sleeve 1004 is moved to its position of Unlocking, shown in particular in FIG. 58a, an upper edge of said control sleeve 1004 comes into contact with said side pieces 1502.
• the thread 1021 will progressively unfold until being stretched at the end of injection as shown in Figure 58b.
• the wire 1021 will exert traction on the central part 1501, causing under the effect of the reaction of the upper edge of the control sleeve 1004, the displacement and / or the deformation of the side pieces.
• 1503 breakable links they break, allowing the side parts 1502 to move above the central part 1501, and therefore the control sleeve 1004 to move axially relative to the outer shell 1022, as visible in particular on the Figure 59a.
• This displacement is done under the pressure exerted by the injection spring 1008 on the control sleeve 1004, it is relatively abrupt and creates a shock between the control sleeve 1004, the side parts 1502 and / or the outer shell 1022.
• This shock is audible and / or tactile for the user, which therefore receives information on the end of injection.
• the wire 1021 is no longer quite taut, as illustrated schematically in FIGS. 59a and 59b.
• Figures 60 to 64c illustrate a second variant of the sound and / or tactile indication device.
• the central piece is removed.
• the audible and / or tactile indication device 1500 comprises a movable element which is here formed by the control sleeve
• This control sleeve 1004 which comprises at its distal end relative to the needle, one or more deformable tabs 1510 which at the end of the injection will abut against the outer shell 1022.
• This control sleeve 1004 is in a first position relative to the outer shell 1022 before actuating the autoinjector, as shown in Figure 64a.
• the opening of the injection lock, and therefore the beginning of the injection phase causes the displacement of the control sleeve 1004 to a second position, visible in Figure 64B.
• a central part called key 1 120 here advantageously replaces the wire of the first previous variant.
• This key 1120 in particular visible in FIGS. 63a and 63b, comprises a rod portion 121 which extends inside the piston rod.
• Key 1 120 also has a head portion 122, disposed at the upper (or distal to the needle) end of said key. This head portion cooperates with said deformable tabs 1510 of the control sleeve 1004, to prevent them from deforming radially towards inside. As a result, these deformable tabs 1510 block said control sleeve in its second position relative to said outer shell 1022.
• the lower end (or proximal to the needle) of the shaft portion 121 interacts with the shaft. 1005 piston at the end of injection, causing a sliding of said key 1 120 relative to the control sleeve 1004 and the outer shell 1022.
• the head portion 122 122 no longer cooperates with the legs 1510 of the control sleeve, which can then deform radially inwardly. This has the effect of unblocking the control sleeve 1004, which is then moved to a third position against said outer shell 1022 under the effect of the force exerted by the injection spring 1008. This creates an audible or otherwise detectable shock by the user, who knows then that the injection is complete.
• the outer shell 1022 comprises one or more, in particular three viewing windows 1023 in which said deformable tabs 1510 become visible at the same time as they come to tap against the outer shell. This allows a visual indication simultaneously with the sound and / or tactile indication.
• said at least one viewing window 1023 is formed on or in the distal end edge of said outer shell 1022, being visible both in the axial direction and in the radial direction of said shell.
• This implementation avoids masking the viewing window (s) 1023 when the autoinjector is taken over by the user, which guarantees a good visualization of the information displayed in said at least one viewing window 1023 during the entire phase of the display. use, from beginning to end.
• several viewing windows 1023 including three, distributed around the distal end edge of the body 1022, perfect viewing is guaranteed regardless of the orientation of the autoinjector at the time of use.
• the alternative embodiments of the second embodiment of the autoinjector described above thus define a control sleeve 1004 having three distinct positions: before injection when it is in position during injection when it is in the unlocking position, and after injection when it has actuated the audible and / or tactile indication device. This makes it easy to visualize these three distinct positions in an appropriate viewing window 1221.
• the outer shell 1022 of this second embodiment could furthermore include several viewing windows as described in the first embodiment.
• Figures 65 to 71 illustrate a third embodiment of the sound and / or tactile indication device.
• the mobile element of the sound and / or tactile indication device is not formed by the control sleeve 1004 but by the support pad 1006 on which FIGS. 66a and 66b show this support pad, which comprises one or more deformable tabs 1520, which are similar to the deformable tabs 1510 of the control sleeve 1004 of the second variant above.
• the operation is also similar, with the key 1 120 which blocks by its head 122 the radial deformation of said tabs 1520, which blocks the support pad relative to the outer shell.
• a visual indication is also provided by one or more viewing windows 1023 of the outer shell which show the deformable tabs 1520 of the support pad 1006.
• Figures 69 to 71 illustrate in more detail the operation of the audible and / or tactile indication device.
• the deformable tab 1520 is prevented from deforming radially inwardly by the presence of the head portion 122 of the wrench 1120.
• the wrench has been moved by the piston rod. and, therefore, the deformable tab 1520 has deformed radially inwardly. This caused the displacement of the support pad 1006 in the outer shell, with a shoulder 1521 of the deformable tab which abuts on a portion of said outer shell, generating the sound and / or tactile indication, for example an audible sound or a vibration sensitive.
• FIG. 71 illustrates the end of the injection, with the piston rod 1005 which will pulling on the shank portion 1 121 of the key 1 120 to move it.
• the present invention applies to devices used in particular for the treatment of autoimmune diseases, for example of the type rheumatoid arthritis, multiple sclerosis, Crohn's disease, for cancer treatments, for antiviral treatments, for example of the type hepatitis, for treatments against diabetes, for treatments against anemia or for treatment of seizures, for example in case of anaphylactic shock.
• autoimmune diseases for example of the type rheumatoid arthritis, multiple sclerosis, Crohn's disease
• cancer treatments for antiviral treatments, for example of the type hepatitis, for treatments against diabetes, for treatments against anemia or for treatment of seizures, for example in case of anaphylactic shock.
• the actuator sleeve and / or the syringe displacement device for the stitching and / or the retraction and / or the injection lock and / or the delay device and / or the sound and / or tactile indication device may be used independently of each other.
• Stitching of the needle and / or retraction of the needle after injection could be controlled by one or more button (s).
• the audible and / or tactile indication device of the second embodiment could be used with an autoinjector of the type described in the first embodiment.
• Other modifications are also possible for those skilled in the art without departing from the scope of the present invention as defined by the appended claims.

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• 2013
  • 2013-05-24 CN CN201380034076.XA patent/CN104394911B/zh active Active
  • 2013-05-24 WO PCT/FR2013/051136 patent/WO2013175136A1/fr active Application Filing
  • 2013-05-24 EP EP13731356.5A patent/EP2854899B1/fr active Active
  • 2013-05-24 JP JP2015513249A patent/JP6196295B2/ja active Active
  • 2013-05-24 IN IN9319DEN2014 patent/IN2014DN09319A/en unknown
  • 2013-05-24 US US14/398,763 patent/US9707357B2/en active Active

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